CN101388463B - Membrane electrode for proton exchange membrane water electrolysis battery and preparation thereof - Google Patents
Membrane electrode for proton exchange membrane water electrolysis battery and preparation thereof Download PDFInfo
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- CN101388463B CN101388463B CN2008102016136A CN200810201613A CN101388463B CN 101388463 B CN101388463 B CN 101388463B CN 2008102016136 A CN2008102016136 A CN 2008102016136A CN 200810201613 A CN200810201613 A CN 200810201613A CN 101388463 B CN101388463 B CN 101388463B
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Abstract
The invention discloses a proton exchange membrane water electrolyte battery membrane electrode and a process for preparation thereof, which belongs to the technical field of preparing hydrogen gas through electrolyzing water, wherein the proton exchange membrane water electrolyte battery membrane electrode comprises a polymer electrolyte membrane, an anode catalyst layer, a cathode catalyst layer, an anode diffusion layer, a cathode diffusion layer, a support layer and a flow field plate, wherein hydrophilic thin layer structures which are formed by catalyst are respectively brushed on both surfaces of the polymer electrolyte membrane. Anode catalyst is noble metal or metallic material, and the diffusion layer is carbon material or metallic material. A catalyst layer and the relative diffusion layer and the support layer are compacted in a titanium plate to prepare membrane electrode through utilizing external force under normal temperature. The invention lowers the load of catalyst,improves the operating factor of catalyst, avoids the deformation of membranes in the process of heat pressing, and is drawn supported from the catalytic and corrosion resistance property of an anti-corrosion diffusion layer with catalytic property, and the electrolytic property and the stability of a battery are improved. The invention has the advantages of simple technique, convenient operationand excellent repeatability.
Description
Technical field
The present invention relates to the electrode in a kind of fuel cell technology field and preparation method thereof, specifically, what relate to is a kind of membrane electrode for proton exchange membrane water electrolysis battery and preparation method thereof.
Background technology
Global energy shortage that the use of fossil fuel causes and environmental problem make the whole world all consider to use the regenerative resource of cleaning to substitute fossil energy.Regenerative resources such as solar energy, wind energy and tidal energy are influenced greatly by environmental change, in use all will carry out store energy, obtain stable energy resource supply to guarantee power consumer.Hydrogen is a kind of cleaning, eco-friendly energy carrier, can be used as a kind of important selection of regenerative resource energy storage technology.Simultaneously, along with development and the continuous expansion of solar-system operation scope and the continuous prolongation of time of manned spaceflight technology, at abundant relatively water source is arranged in the spacecraft, water electrolysis has also become the oxygen source in carrying out long-term space operation process.In multiple water electrolysis method, the proton exchange membrane water electrolysis tech adopts proton exchange membrane as electrolyte, there are not free acid or alkali lye during electrolysis in the system, can not produce etching problem, water is unique free fluid, the factor of created gas height, and weight-volume is relative with power consumption less, gas purity is high and safe and reliable, has been subjected to showing great attention to of people.The exploitation of proton exchange membrane water electrolysis tech has very significant meaning for clean energy resource utilization and universe space flight exploitation.
Membrane electrode is the place that the proton exchange membrane water electrolysis reaction takes place, and anode (oxygen electrode) is one of key technology wherein.Anode is a kind of gas-diffusion electrode, and catalyst wherein generally is Noble Metal Rhodium (Ru), iridium (Ir) etc. or their oxide.Because the noble metal resource scarcity costs an arm and a leg, therefore there is membrane electrode cost problem of higher.In addition, the diffuse layer structure of anode also can have influence on the performance of proton exchange membrane water electrolysis battery and stablize.The proton exchange membrane fuel diffusion layer material all is that material with carbon element (for example prepares at present, carbon paper or carbon cloth), but for proton exchange membrane water electrolysis battery, because during oxygen evolution reaction, the oxidizability of nascent state active oxygen species is very strong, under higher current potential, material with carbon element is easy to oxidized corrosion, thereby influences the diffusion process of gas and water.The more use of membrane electrode preparation method be pressure sintering, dielectric film easy shrinking deformation in hot pressing influences battery electrolysis performance.
Find through literature search prior art, United States Patent (USP) 6, propose anode catalyst in 872,286 and form noble metal carrying capacity height by the oxide of at least a metal or alloy in ruthenium (Ru), iridium (Ir) and iron (Fe), nickel (Ni), the cobalt (Co) or alloy and hopcalite.Its Catalytic Layer is by means of the screen printing method, the catalyst solution brushing is prepared from the carbon paper of handling through PTFE (polytetrafluoroethylene) emulsion, again with dielectric film hot pressing together, make membrane electrode.Because the contact resistance between Catalytic Layer and the film is bigger, and through hot pressing, the easy shrinking deformation of film, thus influence the electrolysis performance of battery.United States Patent (USP) 6,838,205 propose a kind of composite type regenerative fuel cell and oxygen electrode thereof, and its Catalytic Layer directly prepares surface and the diffusion layer ruthenic oxide (RuO at film
2), titanium dioxide (TiO
2) or titanium-ru oxide, titanium carbide electric conducting materials such as (TiC) strengthen the property.Propose a kind of double-effect oxygen electrode that is used for integral regeneratable fuel cell and preparation method thereof among the Chinese patent CN1967916, its diffusion layer is multi-functional diffusion layer.Multi-functional diffusion layer is that the catalysis regulating course is constructed in substrate thereon with material with carbon element or metal material, load has the oxygen-separating catalyst of high electrocatalytic active to construct multi-functional diffusion layer for oxygen evolution reaction on the catalysis regulating course, reduce the oxygen electrode corrosion that oxygen causes of analysing, and then improve the cyclical stability of battery owing to the regenerative fuel cell electrolytic process.Simultaneously, because the kind electrode structure will be taken into account separating out of oxygen and reduce the economic benefits and social benefits performance, the PTFE emulsion that adds in its Catalytic Layer can reduce electric conductivity, and then reduces the performance of water electrolysis reaction.In the above patent, its Catalytic Layer all is non-loaded noble metal, noble metal carrying capacity height, membrane electrode cost height.
Summary of the invention
The objective of the invention is at the deficiencies in the prior art, a kind of membrane electrode for proton exchange membrane water electrolysis battery and preparation method thereof is provided, the expensive problem that solves proton exchange membrane water electrolysis battery anode (oxygen electrode) noble metal catalyst carrying capacity height and cause, reduce Catalytic Layer and intermembranous contact resistance, on the basis of maintenance or the original electric conductivity of enhancing material with carbon element, reduce the corrosion of diffusion layer and the hot compression deformation of avoiding dielectric film.
The present invention is achieved by the following technical solutions:
Membrane electrode for proton exchange membrane water electrolysis battery involved in the present invention comprises polymer dielectric film, anode (oxygen electrode) Catalytic Layer, negative electrode (hydrogen electrode) Catalytic Layer, anode (oxygen electrode) diffusion layer, negative electrode (hydrogen electrode) diffusion layer, supporting layer, flow-field plate.The two sides of polymer dielectric film is coated anode (oxygen electrode) Catalytic Layer, negative electrode (hydrogen electrode) Catalytic Layer respectively, forms the hydrophilic laminate structure of anode (oxygen electrode) Catalytic Layer one polymer dielectric film-negative electrode (hydrogen electrode) Catalytic Layer.Both sides at above-mentioned hydrophilic laminate structure, stack has anode (oxygen electrode) diffusion layer of microcellular structure or negative electrode (hydrogen electrode) diffusion layer, supporting layer, flow-field plate successively respectively, under the normal temperature, utilize external force to compress, form a water electrolytic cell, the diffusion layer of wherein hydrophilic laminate structure and both sides together constitutes " membrane electrode ".
Described anode (oxygen electrode) Catalytic Layer comprises conductive carrier and noble metal nano catalyst, and conductive carrier carried noble metal nanocatalyst powder is coated in the polymer dielectric film surface then, forms coating.
Described conductive carrier is corrosion resistant conductive carrier, can be the nanometer powder of the carbonitride of the carbide of titanium or titanyl compound, titanium or titanium.
Described metal nano catalyst is the noble metal nano catalyst fines that oxygen evolution reaction is had high electrocatalytic active, can be the mixture or the alloy of metal platinum (Pt), iridium (Ir), palladium (Pd), gold (Au), ruthenium (Ru), rhodium (Rh), osmium (Os) and tantalum (Ta) etc., or the nanometer powder of the oxide of these noble metals.
Described anode (oxygen electrode) diffusion layer comprises base material and precious metal material, and precious metal material is coated in substrate surface, forms the anticorrosive diffusion layer with catalytic performance.
The base material of described anode (oxygen electrode) diffusion layer is material with carbon element or the metal material with microcellular structure.
The precious metal material of described anode (oxygen electrode) diffusion layer, for oxygen evolution reaction being had the nanometer powder of the precious metal material of high catalytic activity, anode (oxygen electrode) diffusion layer is the anticorrosive diffusion layer with catalytic performance.
The described precious metal material that oxygen evolution reaction is had a high catalytic activity is the mixture or the alloy of platinum (Pt), iridium (Ir), palladium (Pd), gold (Au), ruthenium (Ru), rhodium (Rh), osmium (Os) and tantalum (Ta) etc., or the nanometer powder of the oxide of these noble metals.
Described anode (oxygen electrode) diffusion layer, thickness is 0.10~0.38mm.
Described negative electrode (hydrogen electrode) diffusion layer, its thickness is 0.10~0.38mm.
Described supporting layer is to be made of the titanium net, thickness 0.10~0.30mm.
The preparation method of membrane electrode for proton exchange membrane water electrolysis battery involved in the present invention may further comprise the steps:
The first step: will on corrosion resistant conductive carrier, obtain anode (oxygen electrode) catalyst to the noble metal nano catalyst cupport that oxygen evolution reaction has a high electrocatalytic active.
Second step: anode (oxygen electrode) catalyst, Nafion solution, isopropanol solvent and deionized water are mixed, wherein Nafion solution (calculating by pure resin) part by weight is 10%~50%, and the part by weight of anode (oxygen electrode) catalyst, Nafion solution (calculating by pure resin), isopropyl alcohol and deionized water is about 7: 3: 98: 10.To be mixed evenly after, spraying, brushing or transfer printing obtain anode (oxygen electrode) Catalytic Layer in the one side of polymer dielectric film.
Described Nafion solution can adopt prior art, such as the perfluor sulfoacid resin solution of du pont company production.
Described polymer dielectric film can adopt prior art, such as the perfluoro sulfonic acid membrane of du pont company production.
The 3rd step: will the nanometer powder that oxygen evolution reaction has a precious metal material of high catalytic activity be mixed with PTFE (polytetrafluoroethylene) emulsion, Nafion solution, aqueous isopropanol and deionized water, wherein the part by weight of Nafion solution (calculating by pure resin) is 10%~50%, and the part by weight of nanometer powder, PTFE (calculating by pure polytetrafluoroethylene), Nafion solution (calculating by pure resin), isopropyl alcohol and deionized water is about 7: 0.3: 3: 98: 10.To be mixed evenly after, brushing is on material with carbon element or metal material base material, as anode (oxygen electrode) diffusion layer.
The 4th step: will have negative electrode (hydrogen electrode) catalyst fines, Nafion solution, aqueous isopropanol and the deionized water mixing of the precious metal material of high electrocatalytic active to evolving hydrogen reaction, wherein Nafion solution (calculating by pure resin) part by weight is 10%~50%, and the part by weight of negative electrode (hydrogen electrode) catalyst, Nafion solution (calculating by pure resin), isopropyl alcohol and deionized water is about 7: 3: 98: 10.To be mixed evenly after, spraying, brushing or transfer printing obtain negative electrode (hydrogen electrode) Catalytic Layer at the another side of polymer dielectric film.
The 5th step: with material with carbon element or metal material as negative electrode (hydrogen electrode) diffusion layer.
The 6th step: with the supporting layer of titanium net as anode (oxygen electrode) and negative electrode (hydrogen electrode).
The 7th step: under the normal temperature, utilize external force to be pressed together Catalytic Layer and corresponding diffusion layer and supporting layer, obtain the membrane electrode of proton exchange membrane water electrolysis battery with the titanium plate that has flow field structure.
The present invention adopts the noble metal nano catalyst of corrosion resistance carrier material load that has the good electrical catalytic performance for oxygen evolution reaction as anode (oxygen electrode) catalyst, reduces the noble metal catalyst carrying capacity.Use has the anticorrosive diffusion layer of catalytic performance, by increasing with the oxygen evolution reaction catalysts is the face coat of main component, solve the corrosion and the problem of oxidation of diffusion layer, simultaneously, the oxygen evolution reaction catalysts in the face coat also plays the effect that strengthens catalysis water electrolysis performance.Adopt hydrophilic laminate structure, directly Preparation of Catalyst is reduced Catalytic Layer and intermembranous contact resistance and the useful life of proper extension Catalytic Layer on proton exchange membrane electrolyte.Under the normal temperature, utilize external force that Catalytic Layer and corresponding diffusion layer and supporting layer are pressed abd fixed in the titanium plate, be prepared into membrane electrode.
Advantage of the present invention and enthusiasm are:
1. noble metal catalyst is loaded on the carrier of the good and antioxidant anticorrosive of electric conductivity, reduce the carrying capacity of noble metal catalyst, improve the utilance of catalyst.
2. on the material with carbon element of anode (oxygen electrode) diffusion layer or metal material base material, make up anticorrosive diffusion layer with catalytic action.By the efficient catalytic effect of diffusion layer for active oxygen species; make active oxygen species before arriving material with carbon element or metal material base material, just can fast reaction generate oxygen; and overflow from the pore of diffusion layer; avoided active oxygen to contact with the diffusion layer base material; played the effect of protection diffusion layer base material, thereby made battery keep long-time steady operation.
3. the anticorrosive diffusion layer that the present invention is prepared with catalytic action, adopt PTFE (polytetrafluoroethylene) emulsion and Nafion solution (perfluor sulfoacid resin solution that du pont company is produced) bi-component binding agent, guaranteed that effectively diffusion layer has suitable hydrophobic hydrophilic nmature, thereby helped the smooth and easy of gas-liquid mass transfer passage.
4. the anticorrosive diffusion layer with catalytic action that the present invention is prepared, it has corrosion-resistant and long-life advantage with respect to traditional material with carbon element diffusion layer, has advantages such as the little and stable performance of contact resistance with respect to corrosion resistant metal material diffusion layer.
5. hydrophilic laminate structure has reduced Catalytic Layer and intermembranous contact resistance, can reduce decomposition voltage, improves electrolytic efficiency.
6. under the normal temperature, utilize external force, Catalytic Layer is pressed in the titanium plate with corresponding diffusion layer and supporting layer prepares membrane electrode, avoided the hot compression deformation and the physical damage of dielectric film.
In a word, characteristics of the present invention are working load type anode (oxygen electrode) nanocatalyst, reduce noble metal catalyst carrying capacity on the pole catalyze layer, improve the utilance of catalyst; Use has the diffusion layer of catalysis oxygen evolution reaction function and the corrosion of anti-active oxygen species, before active oxygen species arrives diffusion layer, react at the diffusion layer quick catalysis, generating oxygen overflows from diffusion layer, protect the diffusion layer of electrode to avoid corrosion, increased substantially the stability of proton exchange membrane water electrolysis battery; Adopt hydrophilic laminate structure, reduced Catalytic Layer and intermembranous contact resistance, prolonged the useful life of Catalytic Layer.Under the normal temperature, utilize external force that Catalytic Layer is pressed in the titanium plate with corresponding diffusion layer and supporting layer and prepare membrane electrode, avoided the hot compression deformation of dielectric film, improve the performance and the stability of proton exchange membrane water electrolysis battery.
Description of drawings
Fig. 1. the assembling assumption diagram of membrane electrode for proton exchange membrane water electrolysis battery;
Among the figure: 1. titanium flow-field plate; 2. supporting layer (titanium net); 3. diffusion layer; 4.Teflon frame; 5. hydrophilic laminate structure (comprising hydrogen catalysis layer, proton exchange membrane and oxygen Catalytic Layer); 6. oxygen Catalytic Layer; 7. water and gas passage; 8. assembling location hole.
Fig. 2. when using different anode (oxygen electrode) diffusion layers, the polarization curve of proton exchange membrane water electrolysis battery and stability curve chart.
Fig. 3. use identical (iridium (Ir) the catalyst loading 0.3mg cm of noble metal carrying capacity
-2) different anodes (oxygen electrode) catalyst the time, the polarization curve of proton exchange membrane water electrolysis battery and stability curve chart.
Embodiment
Below in conjunction with accompanying drawing embodiments of the invention are elaborated: present embodiment is being to implement under the prerequisite with the technical solution of the present invention, provided detailed execution mode and concrete operating process, but protection scope of the present invention is not limited to following embodiment.
Embodiment 1
As shown in Figure 1, the membrane electrode for proton exchange membrane water electrolysis battery that present embodiment relates to comprises flow-field plate 1, supporting layer 2, diffusion layer 3, hydrophilic laminate structure 5, wherein:
Diffusion layer 3 comprises anode (oxygen electrode) diffusion layer, negative electrode (hydrogen electrode) diffusion layer.
Both sides at hydrophilic laminate structure 5, stack has anode (oxygen electrode) diffusion layer of microcellular structure or negative electrode (hydrogen electrode) diffusion layer, supporting layer 3, flow-field plate 1 successively respectively, under the normal temperature, utilize external force to compress, form a water electrolytic cell, wherein hydrophilic laminate structure 5 together constitutes " membrane electrode " with the diffusion layer 3 of both sides.
Also be useful on the general parts of assembling among Fig. 1,, be used for fixing and assemble described membrane electrode for proton exchange membrane water electrolysis battery as Teflon frame 4, water and gas passage 7, assembling location hole 8 etc.
Described polymer dielectric film can adopt existing matured product, and such as the perfluoro sulfonic acid membrane that du pont company is produced, thickness is 50~125 μ m.
Described anode (oxygen electrode) Catalytic Layer comprises conductive carrier and noble metal nano catalyst, and conductive carrier carried noble metal nanocatalyst powder is coated in the polymer dielectric film surface then.
Described conductive carrier is corrosion resistant conductive carrier, can be the nanometer powder of the carbonitride of the carbide of titanium or titanyl compound, titanium or titanium.
Described noble metal nano catalyst is the noble metal nano catalyst fines that oxygen evolution reaction is had high electrocatalytic active, can be the mixture or the alloy of noble metal platinum (Pt), iridium (Ir), palladium (Pd), gold (Au), ruthenium (Ru), rhodium (Rh), osmium (Os) and tantalum (Ta) etc., or the nanometer powder of the oxide of these noble metals.
Described anode (oxygen electrode) diffusion layer comprises base material and precious metal material, and precious metal material is coated in substrate surface.
Described anode (oxygen electrode) diffusion layer, thickness is 0.10~0.38mm.
The base material of described anode (oxygen electrode) diffusion layer is material with carbon element or the metal material with microcellular structure.
The precious metal material of described anode (oxygen electrode) diffusion layer, for oxygen evolution reaction being had the nanometer powder of the precious metal material of high catalytic activity, anode (oxygen electrode) diffusion layer is the anticorrosive diffusion layer with catalytic performance.
Described material with carbon element base material is carbon paper or the carbon cloth with microcellular structure; The metal material base material is expanded metal, foam metal or the wire netting of titanium (Ti), tungsten (W) and molybdenum (Mo) or their oxide, carbide, carbonitride or nitride.
The described precious metal material that oxygen evolution reaction is had a high catalytic activity is the mixture or the alloy of platinum (Pt), iridium (Ir), palladium (Pd), gold (Au), ruthenium (Ru), rhodium (Rh), osmium (Os) and tantalum (Ta) etc., or the nanometer powder of the oxide of these noble metals.
Described negative electrode (hydrogen electrode) Catalytic Layer is the nanometer powder coating of the precious metal material that evolving hydrogen reaction had high electrocatalytic active.
The described precious metal material that evolving hydrogen reaction is had a high electrocatalytic active comprises: platinum (Pt), ruthenium (Ru), the nanometer powder of rhodium (Rh) or gold precious metal simple substances such as (Au) or alloy.
Described negative electrode (hydrogen electrode) diffusion layer is material with carbon element or the metal material with microcellular structure, and its thickness is 0.10~0.38mm.
The material with carbon element of described negative electrode (hydrogen electrode) diffusion layer is carbon paper or the carbon cloth with microcellular structure; Metal material is expanded metal, foam metal or the wire netting of titanium (Ti), tungsten (W) and molybdenum (Mo) or their oxide, carbide, carbonitride or nitride.
Described supporting layer 2 is to be made of the titanium net, thickness 0.10~0.30mm.
Embodiment 2
1. take by weighing the TiC powder of 0.2086 gram, add a small amount of isopropyl alcohol and an amount of redistilled water, suspension-turbid liquid is made in ultrasonic dispersion, adds 0.1162 gram (NH
4)
2IrCl
6, ultrasonic dispersion also is heated to 80 ℃, and constant temperature was held 40 minutes.Drip the reductant solution (HCHO:NH for preparing behind formaldehyde and the ammoniacal liquor mixed diluting
3: H
2O ≈ 2:1:21, percentage by weight), thermostatic ultrasonic reaction 1 hour is cooled to room temperature.To slurries suction filtration, washing, Cl to the filtrate
-Content is lower than 40ppm.In mobile Ar atmosphere, 80 ℃ of dryings 1 hour again in 500 ℃ of heat treatments 30 minutes, promptly get Ir/TiC loaded catalyst (weight ratio 20:80) after the cooling.
2. take by weighing 31 milligrams of Ir/TiC catalyst (weight ratio 20:80), adding 435 milligrams of isopropyl alcohols mixes, Nafion solution (perfluor sulfoacid resin solution that du pont company is produced) and 45 milligrams of deionized waters of adding 270 milligram 5%, after mixing, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 50 μ m) one side, obtain anode (oxygen electrode) Catalytic Layer.
3. take by weighing 22 milligrams of the black catalyst of platinum (Pt), it is wetting to add 2 milligrams of deionized waters, mix with 310 milligrams of isopropyl alcohols, add after 190 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 30 milligrams of deionized waters mix, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 50 μ m) one side, obtain negative electrode (hydrogen electrode) Catalytic Layer.
4. cut 4 * 5cm
2Carbon paper, thickness is 0.20mm, adding 115 milligrams of isopropyl alcohols in the black catalyst of 11 milligrams of iridium (Ir) mixes, add after 0.8 milligram 60% PTFE (polytetrafluoroethylene) emulsion and 90 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 16 milligrams of deionized waters mix, brushing is on carbon paper, 60 ℃ of dryings 30 minutes obtain having erosion-resisting anode (oxygen electrode) diffusion layer of catalytic performance.
5. cut 4 * 5cm again
2Carbon paper, thickness is 0.20mm, is used as negative electrode (hydrogen electrode) diffusion layer.6. cut two thick 4 * 5cm of 0.30mm
2The titanium net be used as the supporting layer of anode (oxygen electrode) and negative electrode (hydrogen electrode) respectively.
7. under the normal temperature, utilize external force that Catalytic Layer and corresponding diffusion layer and supporting layer are pressed in the titanium plate that has flow field structure, promptly obtain the membrane electrode of proton exchange membrane water electrolysis battery.
Embodiment 3
1. take by weighing the TiC powder of 0.2086 gram, add a small amount of isopropyl alcohol and an amount of redistilled water, suspension-turbid liquid is made in ultrasonic dispersion, adds 0.1162 gram (NH
4)
2IrCl
6, ultrasonic dispersion also is heated to 80 ℃, and constant temperature kept 40 minutes.Drip the reductant solution (HCHO:NH for preparing behind formaldehyde and the ammoniacal liquor mixed diluting
3: H
2O ≈ 2:1:21, percentage by weight), thermostatic ultrasonic reaction 1 hour is cooled to room temperature.To slurries suction filtration, washing, Cl to the filtrate
-Content is lower than 40ppm.In mobile Ar atmosphere, 80 ℃ of dryings 1 hour again in 500 ℃ of heat treatments 30 minutes, promptly get Ir/TiC loaded catalyst (weight ratio 20:80) after the cooling.
2. take by weighing 31 milligrams of Ir/TiC catalyst (weight ratio 20:80), adding 435 milligrams of isopropyl alcohols mixes, Nafion solution (perfluor sulfoacid resin solution that du pont company is produced) and 45 milligrams of deionized waters of adding 270 milligram 5%, after mixing, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 50 μ m) one side, obtain anode (oxygen electrode) Catalytic Layer.
3. take by weighing 22 milligrams of the black catalyst of platinum (Pt), it is wetting to add 2 milligrams of deionized waters, mix with 310 milligrams of isopropyl alcohols, add after 190 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 30 milligrams of deionized waters mix, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 50 μ m) one side, obtain negative electrode (hydrogen electrode) Catalytic Layer.
4. cut 4 * 5cm
2Titanium foam, thickness is 0.20mm, adding 115 milligrams of isopropyl alcohols in the black catalyst of 11 milligrams of iridium (Ir) mixes, add after 0.8 milligram 60% PTFE (polytetrafluoroethylene) emulsion and 90 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 16 milligrams of deionized waters mix, brushing is on titanium foam, 60 ℃ of dryings 30 minutes obtain having erosion-resisting anode (oxygen electrode) diffusion layer of catalytic performance.
5. cut 4 * 5cm again
2Titanium foam, thickness is 0.20mm, is used as negative electrode (hydrogen electrode) diffusion layer.
6. cut two thick 4 * 5cm of 0.30mm
2The titanium net be used as the supporting layer of anode (oxygen electrode) and negative electrode (hydrogen electrode) respectively.
7. under the normal temperature, utilize external force that Catalytic Layer and corresponding diffusion layer and supporting layer are pressed in the titanium plate that has flow field structure, promptly obtain the membrane electrode of proton exchange membrane water electrolysis battery.
Embodiment 4
1. take by weighing the TiC powder of 0.2086 gram, add a small amount of isopropyl alcohol and an amount of redistilled water, suspension-turbid liquid is made in ultrasonic dispersion, adds 0.1162 gram (NH
4)
2IrCl
6, ultrasonic dispersion also is heated to 80 ℃, and constant temperature kept 40 minutes.Drip the reductant solution (HCHO:NH for preparing behind formaldehyde and the ammoniacal liquor mixed diluting
3: H
2O ≈ 2:1:21, percentage by weight), thermostatic ultrasonic reaction 1 hour is cooled to room temperature.To slurries suction filtration, washing, Cl to the filtrate
-Content is lower than 40ppm.In mobile Ar atmosphere, 80 ℃ of dryings 1 hour again in 500 ℃ of heat treatments 30 minutes, promptly get Ir/TiC loaded catalyst (weight ratio 20:80) after the cooling.
2. take by weighing 31 milligrams of Ir/TiC catalyst (weight ratio 20:80), adding 435 milligrams of isopropyl alcohols mixes, Nafion solution (perfluor sulfoacid resin solution that du pont company is produced) and 45 milligrams of deionized waters of adding 270 milligram 5%, after mixing, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 85 μ m) one side, obtain anode (oxygen electrode) Catalytic Layer.
3. take by weighing 22 milligrams of the black catalyst of platinum (Pt), it is wetting to add 2 milligrams of deionized waters, mix with 310 milligrams of isopropyl alcohols, add after 190 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 30 milligrams of deionized waters mix, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 85 μ m) one side, obtain negative electrode (hydrogen electrode) Catalytic Layer.
4. cut 4 * 5cm
2Carbon paper, thickness is 0.28mm, adding 115 milligrams of isopropyl alcohols in the black catalyst of 11 milligrams of iridium (Ir) mixes, add after 0.8 milligram 60% PTFE (polytetrafluoroethylene) emulsion and 90 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 16 milligrams of deionized waters mix, brushing is on carbon paper, 60 ℃ of dryings 30 minutes obtain having erosion-resisting anode (oxygen electrode) diffusion layer of catalytic performance.
5. cut 4 * 5cm again
2Carbon paper, thickness is 0.28mm, is used as negative electrode (hydrogen electrode) diffusion layer.
6. cut two thick 4 * 5cm of 0.30mm
2The titanium net be used as the supporting layer of anode (oxygen electrode) and negative electrode (hydrogen electrode) respectively.
7. under the normal temperature, utilize external force that Catalytic Layer and corresponding diffusion layer and supporting layer are pressed in the titanium plate that has flow field structure, promptly obtain the membrane electrode of proton exchange membrane water electrolysis battery.
1. take by weighing the TiC powder of 0.2086 gram, add a small amount of isopropyl alcohol and an amount of redistilled water, suspension-turbid liquid is made in ultrasonic dispersion, adds 0.1162 gram (NH
4)
2IrCl
6, ultrasonic dispersion also is heated to 80 ℃, and constant temperature kept 40 minutes.Drip the reductant solution (HCHO:NH for preparing behind formaldehyde and the ammoniacal liquor mixed diluting
3: H
2O ≈ 2:1:21, percentage by weight), thermostatic ultrasonic reaction 1 hour is cooled to room temperature.To slurries suction filtration, washing, Cl to the filtrate
-Content is lower than 40ppm.In mobile Ar atmosphere, 80 ℃ of dryings 1 hour again in 500 ℃ of heat treatments 30 minutes, promptly get Ir/TiC loaded catalyst (weight ratio 20:80) after the cooling.
2. take by weighing 31 milligrams of Ir/TiC catalyst (weight ratio 20:80), adding 435 milligrams of isopropyl alcohols mixes, Nafion solution (perfluor sulfoacid resin solution that du pont company is produced) and 45 milligrams of deionized waters of adding 270 milligram 5%, after mixing, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 85 μ m) one side, obtain anode (oxygen electrode) Catalytic Layer.
3. take by weighing 22 milligrams of the black catalyst of platinum (Pt), it is wetting to add 2 milligrams of deionized waters, mix with 310 milligrams of isopropyl alcohols, add after 190 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 30 milligrams of deionized waters mix, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 85 μ m) one side, obtain negative electrode (hydrogen electrode) Catalytic Layer.
4. cut 4 * 5cm
2Carbon paper, thickness is 0.38mm, adding 115 milligrams of isopropyl alcohols in 11 milligrams of Ir/TiC catalyst mixes, add after 0.8 milligram 60% PTFE (polytetrafluoroethylene) emulsion and 90 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 16 milligrams of deionized waters mix, brushing is on carbon paper, 60 ℃ of dryings 30 minutes obtain having erosion-resisting anode (oxygen electrode) diffusion layer of catalytic performance.
5. cut 4 * 5cm again
2Carbon paper, thickness is 0.38mm, is used as negative electrode (hydrogen electrode) diffusion layer.
6. cut two thick 4 * 5cm of 0.30mm
2The titanium net be used as the supporting layer of anode (oxygen electrode) and negative electrode (hydrogen electrode) respectively.
7. under the normal temperature, utilize external force that Catalytic Layer and corresponding diffusion layer and supporting layer are pressed in the titanium plate that has flow field structure, promptly obtain the membrane electrode of proton exchange membrane water electrolysis battery.
Embodiment 6
1. take by weighing the TiC powder of 0.2086 gram, add a small amount of isopropyl alcohol and an amount of redistilled water, suspension-turbid liquid is made in ultrasonic dispersion, adds 0.1162 gram (NH
4)
2IrCl
6, ultrasonic dispersion also is heated to 80 ℃, and constant temperature kept 40 minutes.Drip the reductant solution (HCHO:NH for preparing behind formaldehyde and the ammoniacal liquor mixed diluting
3: H
2O ≈ 2:1:21, percentage by weight), thermostatic ultrasonic reaction 1 hour is cooled to room temperature.To slurries suction filtration, washing, Cl to the filtrate
-Content is lower than 40ppm.In mobile Ar atmosphere, 80 ℃ of dryings 1 hour again in 500 ℃ of heat treatments 30 minutes, promptly get Ir/TiC loaded catalyst (weight ratio 20:80) after the cooling.
2. take by weighing 31 milligrams of Ir/TiC catalyst (weight ratio 20:80), adding 435 milligrams of isopropyl alcohols mixes, Nafion solution (perfluor sulfoacid resin solution that du pont company is produced) and 45 milligrams of deionized waters of adding 270 milligram 5%, after mixing, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 125 μ m) one side, obtain anode (oxygen electrode) Catalytic Layer.
3. take by weighing 22 milligrams of the black catalyst of platinum (Pt), it is wetting to add 2 milligrams of deionized waters, mix with 310 milligrams of isopropyl alcohols, add after 190 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 30 milligrams of deionized waters mix, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 125 μ m) one side, obtain negative electrode (hydrogen electrode) Catalytic Layer.
4. cut 4 * 5cm
2Titanium foam, thickness is 0.20mm, adding 115 milligrams of isopropyl alcohols in 11 milligrams of Ir/TiC catalyst mixes, add after 0.8 milligram 60% PTFE (polytetrafluoroethylene) emulsion and 90 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 16 milligrams of deionized waters mix, brushing is on titanium foam, 60 ℃ of dryings 30 minutes obtain having erosion-resisting anode (oxygen electrode) diffusion layer of catalytic performance.
5. cut 4 * 5cm again
2Titanium foam, thickness is 0.20mm, is used as negative electrode (hydrogen electrode) diffusion layer.
6. cut two thick 4 * 5cm of 0.30mm
2The titanium net be used as the supporting layer of anode (oxygen electrode) and negative electrode (hydrogen electrode) respectively.
7. under the normal temperature, utilize external force that Catalytic Layer and corresponding diffusion layer and supporting layer are pressed in the titanium plate that has flow field structure, promptly obtain the membrane electrode of proton exchange membrane water electrolysis battery.
1. take by weighing the TiC powder of 0.2086 gram, add a small amount of isopropyl alcohol and an amount of redistilled water, suspension-turbid liquid is made in ultrasonic dispersion, adds 0.1162 gram (NH
4)
2IrCl
6, ultrasonic dispersion also is heated to 80 ℃, and constant temperature kept 40 minutes.Drip the reductant solution (HCHO:NH for preparing behind formaldehyde and the ammoniacal liquor mixed diluting
3: H
2O ≈ 2:1:21, percentage by weight), thermostatic ultrasonic reaction 1 hour is cooled to room temperature.To slurries suction filtration, washing, Cl to the filtrate
-Content is lower than 40ppm.In mobile Ar atmosphere, 80 ℃ of dryings 1 hour again in 500 ℃ of heat treatments 30 minutes, promptly get Ir/TiC loaded catalyst (weight ratio 20:80) after the cooling.
2. take by weighing 31 milligrams of Ir/TiC catalyst (weight ratio 20:80), adding 435 milligrams of isopropyl alcohols mixes, Nafion solution (perfluor sulfoacid resin solution that du pont company is produced) and 45 milligrams of deionized waters of adding 270 milligram 5%, after mixing, spraying, brushing or transfer printing are at the polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 125 μ m) one side, obtain anode (oxygen electrode) Catalytic Layer.
3. take by weighing 22 milligrams of the black catalyst of platinum (Pt), it is wetting to add 2 milligrams of deionized waters, mix with 310 milligrams of isopropyl alcohols, Nafion solution (perfluor sulfoacid resin solution that du pont company is produced) and 30 milligrams of deionized waters of adding 190 milligram 5%, after mixing, spraying, brushing or transfer printing obtain negative electrode (hydrogen electrode) Catalytic Layer in the one side of polymer dielectric film (perfluoro sulfonic acid membrane that du pont company is produced, thickness is 125 μ m).
4. cut 4 * 5cm
2Carbon cloth, thickness is 0.10mm, adding 115 milligrams of isopropyl alcohols in 11 milligrams of Ir/TiC catalyst mixes, add after 0.8 milligram 60% PTFE (polytetrafluoroethylene) emulsion and 90 milligram 5% Nafion solution (du pont company produce perfluor sulfoacid resin solution) and 16 milligrams of deionized waters mix, brushing is on carbon cloth, 60 ℃ of dryings 30 minutes obtain having erosion-resisting anode (oxygen electrode) diffusion layer of catalytic performance.
5. cut 4 * 5cm again
2Carbon cloth, thickness is 0.10mm, is used as negative electrode (hydrogen electrode) diffusion layer.
6. cut two thick 4 * 5cm of 0.30mm
2The titanium net be used as the supporting layer of anode (oxygen electrode) and negative electrode (hydrogen electrode) respectively.
7. under the normal temperature, utilize external force that Catalytic Layer and corresponding diffusion layer and supporting layer are pressed in the titanium plate that has flow field structure, promptly obtain the membrane electrode of proton exchange membrane water electrolysis battery.
Because the present invention adopts hydrophilic laminate structure, as shown in Figure 1, Catalytic Layer and intermembranous contact resistance have been reduced, under the normal temperature, utilize the external force effect that Catalytic Layer is pressed in the titanium plate with corresponding diffusion layer and supporting layer and prepare membrane electrode, avoided the hot compression deformation of dielectric film.
As shown in Figure 2, when using different anode (oxygen electrode) diffusion layers, the polarization curve of proton exchange membrane water electrolysis battery and stability curve.Anode (oxygen electrode) iridium (Ir) catalyst loading 1.5mgcm, negative electrode (hydrogen electrode) platinum (Pt) catalyst loading 1.0mgcm
-2, the perfluorinated sulfonic acid film thickness is 50 μ m, and the diffusion layer base material is the thick carbon paper of 0.20mm, and supporting layer is the thick titanium net of 0.30mm, battery effective area 4 * 5cm
2, 80 ℃ of water electrolysis temperature, discharge 10mlmin
-1By curvilinear motion shown in Figure 2 as can be seen, use anticorrosive diffusion layer and the diffusion layer phase ratio that does not use face coat with catalytic performance, its electrolysis performance is improved to some extent, and the current density that electrolysis produces under 2V voltage is from 2166mAcm
-2Rise to 2243mAcm
-2The stability of its long-time electrolysis performance also is improved simultaneously, and the current density change of 4 hours front and back of electrolysis is from 218mAcm under 1.60V voltage
-2Be reduced to 170mAcm
-2
As shown in Figure 3, use identical (iridium (Ir) the catalyst loading 0.3mg cm of noble metal carrying capacity
-2) different anodes (oxygen electrode) catalyst the time, the polarization curve of proton exchange membrane water electrolysis battery and stability curve.Wherein, anode (oxygen electrode) diffusion layer uses the anticorrosive diffusion layer with catalytic action, negative electrode (hydrogen electrode) platinum (Pt) catalyst loading 1.0mg cm
-2, the perfluorinated sulfonic acid film thickness is 50 μ m, and the diffusion layer base material is the thick carbon paper of 0.20mm, and supporting layer is the thick titanium net of 0.30mm, 80 ℃ of water electrolysis temperature, discharge 10ml min
-1By curvilinear motion shown in Figure 3 as can be seen, working load type noble metal nano catalyst, improved the utilance of noble metal catalyst, significantly reduced the catalysis cost, when the precious metal catalyst agent content is identical, loaded catalyst is compared with non-loaded catalyst, and the current density that electrolysis produces under 2V voltage is from 1293mA cm
-2Rise to 1463mA cm
-2The stability of its electrolysis performance has also obtained raising to a certain degree simultaneously, and the current density change of 4 hours front and back of electrolysis is from 92mA cm under 1.60V voltage
-2Be reduced to 59mA cm
-2
Claims (9)
1. membrane electrode for proton exchange membrane water electrolysis battery, comprise polymer dielectric film, anode catalyst layer, cathode catalysis layer, anode diffusion layer, cathode diffusion layer, supporting layer, flow-field plate, it is characterized in that: described polymer dielectric film two sides is coated anode Catalytic Layer, cathode catalysis layer respectively, form the hydrophilic laminate structure of anode catalyst layer-polymer dielectric film-cathode catalysis layer, both sides at this hydrophilic laminate structure, stack has the anode diffusion layer of microcellular structure or cathode diffusion layer, supporting layer, flow-field plate successively respectively, wherein:
Described anode catalyst layer comprises conductive carrier and noble metal nano catalyst, and conductive carrier carried noble metal nanocatalyst powder is coated in the polymer dielectric film surface then, forms coating; Described noble metal nano catalyst is the noble metal nano catalyst fines that oxygen evolution reaction is had high electrocatalytic active, is the mixture or the alloy of platinum, iridium, palladium, gold, ruthenium, rhodium, osmium and tantalum, or the nanometer powder of the oxide of these noble metals;
Described anode diffusion layer comprises base material and precious metal material, and precious metal material is coated in substrate surface, forms the anticorrosive diffusion layer with catalytic performance.
2. membrane electrode for proton exchange membrane water electrolysis battery according to claim 1 is characterized in that, described conductive carrier is the nanometer powder of the carbonitride of the carbide of titanium or titanyl compound, titanium or titanium.
3. membrane electrode for proton exchange membrane water electrolysis battery according to claim 1 is characterized in that, the base material of described anode diffusion layer is material with carbon element or metal material.
4. membrane electrode for proton exchange membrane water electrolysis battery according to claim 1, it is characterized in that, the precious metal material of described anode diffusion layer is for having the nanometer powder of the precious metal material of high catalytic activity to oxygen evolution reaction, specifically be meant the mixture or the alloy of platinum, iridium, palladium, gold, ruthenium, rhodium, osmium and tantalum, or the nanometer powder of the oxide of these noble metals.
5. membrane electrode for proton exchange membrane water electrolysis battery according to claim 1 is characterized in that, described anode diffusion layer, thickness are 0.10~0.38mm.
6. membrane electrode for proton exchange membrane water electrolysis battery according to claim 1 is characterized in that, described cathode diffusion layer, its thickness are 0.10~0.38mm.
7. membrane electrode for proton exchange membrane water electrolysis battery according to claim 1 is characterized in that, described supporting layer is to be made of the titanium net, thickness 0.10~0.30mm.
8. membrane electrode for proton exchange membrane water electrolysis battery according to claim 1 is characterized in that, described polymer dielectric film, thickness are 50~125 μ m.
9. the preparation method of a membrane electrode for proton exchange membrane water electrolysis battery as claimed in claim 1 is characterized in that, may further comprise the steps:
The first step: will on corrosion resistant conductive carrier, obtain anode catalyst to the noble metal nano catalyst cupport that oxygen evolution reaction has a high electrocatalytic active;
Second step: anode catalyst, Nafion solution, isopropanol solvent and deionized water are mixed, wherein Nafion solution is 10%~50% in pure resin calculated weight ratio, anode catalyst, Nafion solution are 7: 3: 98 by the part by weight of pure resin calculating, isopropyl alcohol and deionized water: 10, to be mixed evenly after, spraying, brushing or transfer printing obtain anode catalyst layer in the one side of polymer dielectric film;
The 3rd step: will the nanometer powder that oxygen evolution reaction has a precious metal material of high catalytic activity be mixed with polytetrafluoroethylene PTFE emulsion, Nafion solution, aqueous isopropanol and deionized water, wherein Nafion solution is 10%~50% by the part by weight that pure resin calculates, nanometer powder, PTFE by pure polytetrafluoroethylene calculate, Nafion solution is 7: 0.3: 3 by the part by weight of pure resin calculating, isopropyl alcohol and deionized water: 98: 10, to be mixed evenly after, brushing is on material with carbon element or metal material base material, as anode diffusion layer;
The 4th step: will have cathod catalyst powder, Nafion solution, aqueous isopropanol and the deionized water mixing of the precious metal material of high electrocatalytic active to evolving hydrogen reaction, wherein Nafion solution is 10%~50% in pure resin calculated weight ratio, cathod catalyst, Nafion solution are 7: 3: 98 by the part by weight of pure resin calculating, isopropyl alcohol and deionized water: 10, to be mixed evenly after, spraying, brushing or transfer printing obtain cathode catalysis layer at the another side of polymer dielectric film;
The 5th step: with material with carbon element or metal material as cathode diffusion layer;
The 6th step: with the supporting layer of titanium net as anode and negative electrode;
The 7th step: under the normal temperature, utilize external force to be pressed together Catalytic Layer and corresponding diffusion layer and supporting layer, obtain the membrane electrode of proton exchange membrane water electrolysis battery with the titanium plate that has flow field structure.
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